High contrast inverse polarizer

ABSTRACT

An embedded wire-grid polarizer (WGP) can include ribs  13  located over a surface of a transparent substrate  11 , gaps  16  between the ribs  13 , and a fill-layer  15  substantially filling the gaps  16 . The fill-layer can have a relatively high index of refraction, such as greater than 1.4. At a wavelength of light incident upon the WGP, E ∥  transmission can be greater than E ⊥  transmission. E ∥  is a polarization of light with an electric field oscillation parallel to a length L of the ribs, and E ⊥  is a polarization of light with an electric field oscillation perpendicular to a length L of the ribs. This embedded, inverse WGP is especially useful for polarizing, with high WGP performance, small wavelength (high-energy) regions of the electromagnetic spectrum (e.g. UV) which are difficult to polarize with conventional WGPs (E ⊥  transmission &gt;E ∥  transmission).

CLAIM OF PRIORITY

This application is a continuation of U.S. patent application Ser. No. 15/631,164, filed on Jun. 23, 2017, which is a continuation-in-part of U.S. patent application Ser. No. 15/006,566, filed on Jan. 26, 2016, which claims priority to U.S. Provisional Patent Application No. 62/113,101, filed on Feb. 6, 2015, which are incorporated herein by reference in their entirety.

FIELD OF THE INVENTION

The present application is related generally to wire-grid polarizers.

BACKGROUND

Wire-grid polarizers (WGPs or WGP for singular) can be used to divide light into two different polarization states. One polarization state can mostly pass through the WGP and the other can be mostly absorbed or reflected. The effectiveness or performance of WGPs is based on a high percent transmission of one polarization and minimal transmission of an opposite polarization. A percent transmission of the primarily-transmitted polarization divided by a percent transmission of the opposite polarization is called contrast. It can be difficult to manufacture WGPs that provide sufficiently-high contrast. High contrast can sometimes be obtained by reducing the pitch of the wires/ribs, but doing so can be a difficult manufacturing challenge, especially for smaller wavelengths. It would be beneficial to find a way to improve WGP performance by some way other than a reduction in pitch.

SUMMARY

It has been recognized that it would be advantageous to improve wire-grid polarizer (WGP or WGPs for plural) performance by some way other than a reduction in pitch. The present invention is directed to various embodiments of embedded, inverse WGPs, methods of polarizing light, and methods of designing embedded, inverse WGPs, that satisfy these needs. Each embodiment may satisfy one, some, or all of these needs.

In one embodiment, an embedded, inverse wire-grid polarizer (WGP) can comprising ribs over a transparent substrate, gaps between the ribs, and a fill-layer substantially filling the gaps. The ribs can be metallic. At a wavelength of light incident upon the WGP in a range ≥175 nm, E_(∥) transmission >E_(⊥) transmission, where E_(∥) is a polarization of the light with an electric field oscillation parallel to a length of the ribs and E_(⊥) is a polarization of the light with an electric field oscillation perpendicular to a length of the ribs. Also, at the wavelength of the light, the ribs can be reflective, the fill-layer can be transparent, and the fill-layer can have an index of refraction greater than 1.7.

In another embodiment, an embedded, inverse WGP can comprise ribs over a transparent substrate, gaps between the ribs, and a fill-layer substantially filling the gaps. The fill-layer can also extend from the gaps over the ribs such that the fill-layer in each gap extends continuously over adjacent ribs to the fill-layer in each adjacent gap. The fill-layer can be transparent and can have an index of refraction greater than 1.7. At a wavelength of light incident upon the WGP in a range ≤175 nm, E_(∥) transmission >E_(⊥) transmission.

In another embodiment, an embedded, inverse WGP can comprise ribs over a transparent substrate, gaps between the ribs, and a fill-layer substantially filling the gaps. The fill-layer can comprise aluminum oxide.

BRIEF DESCRIPTION OF THE DRAWINGS (DRAWINGS MIGHT NOT BE DRAWN TO SCALE)

FIG. 1a is a schematic cross-sectional side view of an embedded, inverse wire-grid polarizer (WGP) 10 comprising ribs 13 located over a surface of a transparent substrate 11, gaps 16 between the ribs 13, and a fill-layer 15 substantially filling the gaps 16, in accordance with an embodiment of the present invention.

FIG. 1b is a schematic perspective-view of an embedded, inverse wire-grid polarizer (WGP) 10 comprising ribs 13 located over a surface of a transparent substrate 11, gaps 16 between the ribs 13, and a fill-layer 15 substantially filling the gaps 16, in accordance with an embodiment of the present invention.

FIG. 2 is a schematic cross-sectional side view of WGP 20, similar to WGP 10, except that the fill-layer 15 of WGP 20 extends from the gaps 16 over the ribs 13, in accordance with an embodiment of the present invention.

FIG. 3 is a schematic cross-sectional side view of WGP 30, similar to WGPs 10 & 20, except that the ribs 13 of WGP 30 include a substantial difference between a lower-rib-width W_(L) and an upper-rib-width W_(H), in accordance with an embodiment of the present invention.

FIG. 4 is a schematic perspective view of an integrated circuit (IC) inspection tool 40, using at least one WGP 44 to polarize light 45, in accordance with an embodiment of the present invention.

FIG. 5 is a schematic perspective view of a flat panel display (FPD) manufacturing tool 50, using at least one WGP 54 to polarize light 55, in accordance with an embodiment of the present invention.

DEFINITIONS

As used herein, the term “elongated” means that a length L (see FIG. 1b ) of the ribs 13 is substantially greater than rib width W or rib thickness Th₁₃ (see FIGS. 1a , 2, and 3). For example, WGPs for ultraviolet or visible light can have a rib width W between 20 and 100 nanometers and rib thickness between 50 and 500 nanometers; and rib length of about 1 millimeter to 20 centimeters or more, depending on the application. Thus, elongated ribs 13 can have a length L that is many times (e.g. at least 10 times in one aspect, at least 100 times in another aspect, at least 1000 times in another aspect, or at least 10,000 times in another aspect) larger than rib width W or rib thickness Th₁₃.

As used herein, the values of the “index of refraction” mean the values of the real part of the index, not the values of the imaginary part of the index, also known as the extinction coefficient.

As used herein, the term “light” can mean light or electromagnetic radiation in the x-ray, ultraviolet, visible, and/or infrared, or other regions of the electromagnetic spectrum.

As used herein, the term “nm” means nanometer(s).

As used herein, the term “thin-film layer” means a continuous layer that is not divided into a grid.

As used herein, the term “width” of the rib means the maximum width of the rib, unless specified otherwise.

Many materials used in optical structures absorb some light, reflect some light, and transmit some light. The following definitions are intended to distinguish between materials or structures that are primarily absorptive, primarily reflective, or primarily transparent. Each material can be primarily absorptive, primarily reflective, or primarily transparent in a specific wavelength of interest (e.g. all or a portion of the ultraviolet, visible, or infrared spectrums of light) and can have a different property in a different wavelength of interest.

-   -   1. As used herein, the term “absorptive” means substantially         absorptive of light in the wavelength of interest.         -   a. Whether a material is “absorptive” is relative to other             materials used in the polarizer. Thus, an absorptive             structure will absorb substantially more than a reflective             or a transparent structure.         -   b. Whether a material is “absorptive” is dependent on the             wavelength of interest. A material can be absorptive in one             wavelength range but not in another.         -   c. In one aspect, an absorptive structure can absorb greater             than 40% and reflect less than 60% of light in the             wavelength of interest (assuming the absorptive structure is             an optically thick film—i.e. greater than the skin depth             thickness).         -   d. In another aspect, an absorptive material can have a high             extinction coefficient (k), relative to a transparent             material, such as for example greater than 0.01 in one             aspect or greater than 1.0 in another aspect.         -   e. Absorptive ribs can be used for selectively absorbing one             polarization of light.     -   2. As used herein, the term “reflective” means substantially         reflective of light in the wavelength of interest.         -   a. Whether a material is “reflective” is relative to other             materials used in the polarizer. Thus, a reflective             structure will reflect substantially more than an absorptive             or a transparent structure.         -   b. Whether a material is “reflective” is dependent on the             wavelength of interest. A material can be reflective in one             wavelength range but not in another. Some wavelength ranges             can effectively utilize highly reflective materials. At             other wavelength ranges, especially lower wavelengths where             material degradation is more likely to occur, the choice of             materials may be more limited and an optical designer may             need to accept materials with a lower reflectance than             desired.         -   c. In one aspect, a reflective structure can reflect greater             than 80% and absorb less than 20% of light in the wavelength             of interest (assuming the reflective structure is an             optically thick film—i.e. greater than the skin depth             thickness).         -   d. Metals are often used as reflective materials.         -   e. Reflective wires can be used for separating one             polarization of light from an opposite polarization of             light.     -   3. As used herein, the term “transparent” means substantially         transparent to light in the wavelength of interest.         -   a. Whether a material is “transparent” is relative to other             materials used in the polarizer. Thus, a transparent             structure will transmit substantially more than an             absorptive or a reflective structure.         -   b. Whether a material is “transparent” is dependent on the             wavelength of interest. A material can be transparent in one             wavelength range but not in another.         -   c. In one aspect, a transparent structure can transmit             greater than 90% and absorb less than 10% of light at the             wavelength of interest or wavelength range of use, ignoring             Fresnel reflection losses.         -   d. In another aspect, a transparent structure can have an             extinction coefficient (k) of less than 0.01, less than             0.001, or less than 0.0001 in another aspect, at the             wavelength of interest or wavelength range of use.     -   4. As used in these definitions, the term “material” refers to         the overall material of a particular structure. Thus, a         structure that is “absorptive” is made of a material that as a         whole is substantially absorptive, even though the material may         include some reflective or transparent components. Thus for         example, a rib made of a sufficient amount of absorptive         material so that it substantially absorbs light is an absorptive         rib even though the rib may include some reflective or         transparent material embedded therein.

DETAILED DESCRIPTION

As illustrated in FIGS. 1a, 1b , 2, and 3, embedded, inverse wire-grid polarizers (WGPs or WGP for singular) 10, 20, and 30 are shown comprising ribs 13 located over a surface of a transparent substrate 11. The ribs 13 can be elongated and can be formed into an array. The ribs 13 can be reflective, or can include a reflective portion. The ribs 13 can include an absorptive portion. The ribs 13 can be a metal or a dielectric or can include different regions, at least one of which is a metal and at least one of which is a dielectric.

For the following discussion, E_(∥) is a polarization of light with an electric field oscillation parallel to a length L of the ribs and E_(⊥) is a polarization of light with an electric field oscillation perpendicular to a length L of the ribs. In typical WGP use, E_(⊥) is primarily transmitted and E_(∥) is primarily reflected or absorbed. A WGP can be used as an inverse WGP in a wavelength range of light where E_(∥) is primarily transmitted and E_(⊥) is primarily reflected or absorbed (E_(∥) transmission >E_(⊥) transmission). Merely having E_(∥) transmission >E_(⊥) transmission is insufficient for many applications, and it can be important to optimize performance of the inverse WGP, meaning a high E_(∥) transmission and/or high contrast (E_(∥) transmission/E_(⊥) transmission). The WGP structure can be optimized for improved inverse WGP performance.

The WGPs 10, 20, and 30 can have gaps 16 between the ribs 13. The term “gap” means a space, opening, or divide, separating one rib from another rib. A fill-layer 15, substantially filling the gaps 16, and especially a fill-layer 15 with a relatively large index of refraction, can improve inverse WGP performance. For example, an index of refraction of the fill-layer 15 can be greater than 1.4 in one aspect, greater than 1.5 in another aspect, greater than 1.6 in another aspect, greater than 1.7 in another aspect, greater than 1.75 in another aspect, greater than 1.8 in another aspect, greater than 1.9 in another aspect, greater than 2.0 in another aspect, or greater than 2.1 in another aspect. The aforementioned index of refraction values are those at the light wavelength of intended use (e.g. ≥100 nm, ≥150 nm, ≥175 nm, ≥200 nm, ≥250 nm, ≥300 nm, ≥400 nm, or ≥700 nm; and ≤200 nm, ≤250 nm, ≤300 nm, ≤400 nm, ≤700 nm, or ≤1000 nm), where E_(∥) transmission >E_(⊥) transmission. The fill-layer 15 can be a solid material or liquid. The fill-layer 15 can be transparent. Examples of fill-layer materials, for polarization of ultraviolet light, include aluminum oxide (Al₂O₃, n=1.81 at λ=300 nm), zirconium oxide (ZrO₂, n=2.25 at λ=361 nm), and hafnium oxide (HfO₂, n=2.18 at λ=365 nm). Other examples of fill-layer materials include silicon nitride, tantalum oxide, tellurium oxide, germanium oxide, transition metal oxides, oxides of elements with an atomic number ≥20, and rare earth oxides (atomic numbers 21, 39, and 57-71).

Use of a fill-layer 15 to improve WGP performance, and especially use of a fill-layer with a relatively large index of refraction, is contrary to conventional WGP design theory. For example, see U.S. Pat. No. 6,288,840, column 6, line 59 through column 7, line 15. A conventional WGP (E_(⊥) transmission >E_(∥) transmission) may include a fill-layer for protection of the ribs, accepting a reduction in WGP performance. For example, see U.S. Pat. No. 6,288,840, column 1, lines 18-54.

The fill-layer 15 of WGPs 20 and 30 in FIGS. 2-3 substantially fills the gaps 16 and extends from the gaps 16 over the ribs 13 such that the fill-layer 15 in each gap 16 extends continuously over adjacent ribs 13 to the fill-layer 15 in each adjacent gap 16. Extending the fill-layer 15 over the ribs 13, and using certain thicknesses Th₁₅ of the fill-layer 15 over the ribs 13, can improve inverse WGP performance. The fill-layer 15 can extend over the ribs for a thickness Th₁₅ optimized for the desired wavelength range of use. For example, the fill-layer 15 can extend over the ribs for a thickness Th₁₅ of at least 25 nanometers in one aspect, at least 50 nanometers in another aspect, or at least 60 nanometers in another aspect, and less than 90 nanometers in one aspect, less than 100 nanometers in another aspect, or less than 150 nanometers in another aspect.

Use of a substrate 11 and/or a thin-film layer 31 (see FIG. 3) between the ribs 13 and the substrate 11, with a relatively large index of refraction, can improve inverse WGP performance and can shift the wavelength range at which E_(∥) transmission >E_(⊥) transmission. For example, an index of refraction of the substrate 11 and/or the thin-film layer 31 can be greater than 1.4 in one aspect, greater than 1.5 in another aspect, greater than 1.6 in another aspect, or greater than 1.8 in another aspect. The aforementioned index of refraction values are those at the light wavelength of intended use, where E_(∥) transmission >E_(⊥) transmission.

Rib 13 pitch P can be selected to improve inverse WGP performance and to shift the wavelength range at which E_(∥) transmission >E_(⊥) transmission. In conventional WGPs, the pitch needed for high-performance polarization can be less than one-half of the smallest wavelength in the desired polarization wavelength range. Consequently, a pitch of less than 150 nanometers is typically used for polarization of visible light (λ/P≈150/400=2.67), and around 100 nanometers or less for polarization of ultraviolet light. Manufacture of such polarizers can be difficult and costly due to this small pitch. Fortunately, optimal pitch P, for inverse WGPs described herein, can be larger than a pitch needed for conventional polarizers, thus improving the manufacturability of these inverse WGPs.

For example, the wavelength of the light of desired inverse polarization divided by a pitch P of the ribs 13 can be less than 2.5 in one aspect, less than 2.0 in another aspect, less than 1.9 in another aspect, less than 1.8 in another aspect, or less than 1.7 in another aspect. As another example, for inverse polarization of light with a wavelength of less than 400 nanometers (e.g. ultraviolet light), a pitch P of the ribs 13 can be greater than 140 nanometers. Pitch P of the ribs 13 and an index of refraction n of the fill-material 15 can be selected by the following equation: P*(n−0.2)<λ<P*(n+0.2), where λ is the wavelength of the light of desired inverse polarization.

Although pitch P for inverse polarization may be relatively large, for polarization of small wavelengths of light, such as less than 260 nanometer light in one aspect or less than 200 nanometer light in another aspect, small pitches P may be needed, such as for example less than 100 nanometers in one aspect, less than 80 nanometers in another aspect, or even less than 60 nanometers in another aspect.

A duty-cycle (W/P) of the ribs 13 can be selected to improve inverse WGP performance and to shift the wavelength range at which E_(∥) transmission >E_(⊥) transmission. For example, the following duty-cycles can improve contrast: greater than 0.45 in one aspect or greater than 0.55 in another aspect, and less than 0.60 in one aspect, less than 0.65 in another aspect, less than 0.70 in another aspect, or less than 0.80 in another aspect.

A lower duty-cycle can be selected to improve transmission of E_(∥), and can broaden the wavelength range of high E_(∥) transmission, but possibly by sacrificing contrast. Thus, a duty-cycle can be selected for improved transmission of E_(∥), such as for example less than 0.7 in one aspect, less than 0.6 in another aspect, less than 0.5 in another aspect, or less than 0.4 in another aspect. For example, for a wavelength range of light of at least 30 nanometers, E_(∥) transmission >E_(⊥) transmission and E_(∥) transmission can be greater than 80%. This wavelength range of light can be in a region of the electromagnetic spectrum of less than 400 nanometers, e.g. ultraviolet spectrum.

A smaller rib thickness Th₁₃ can improve contrast. For example, rib thickness Th₁₃ can be less than 70 nanometers in one aspect, less than 55 nanometers in another aspect, or less than 45 nanometers in another aspect.

Rib 13 shape can be selected to improve inverse WGP performance and to shift the wavelength range at which E_(∥) transmission >E_(⊥) transmission. Edges E (i.e. corners) of the ribs 13 can be approximately 90 degrees, thus forming rectangular-shaped ribs 13, as shown in FIGS. 1a and 1b . Alternatively, the edges E of the ribs 13 can be rounded, and thus a cross-sectional-profile of the ribs 13 can include a rounded shape, as shown in FIGS. 2-3. One, two, three, or more than three of the edges E of each rib 13 can be rounded. An end of the ribs 13 farther from the substrate (i.e. top of the ribs 13) can have a rounded-shape and/or an end of the ribs 13 closest to the substrate (i.e. bottom of the ribs 13) can be rounded. The ribs 13 can be formed with different shapes by adjusting the anisotropic/isotropic character of the etch, and other etch parameters, throughout the etch process.

Ribs 13 with multiple widths W_(L) and W_(H) in each rib 13, as shown on WGP 30 in FIG. 3, can broaden the wavelength range of high contrast. For example, a difference between a lower-rib-width W_(L) and an upper-rib-width W_(H) can be greater than 10 nanometers in one aspect, greater than 20 nanometers in another aspect, or greater than 30 nanometers in another aspect. Lower-rib-width W_(L) means a maximum width of the ribs 13 in a lower-half of the rib 13 closer to the substrate 11. Upper-rib-width W_(H) means a maximum width of the ribs 13 in an upper-half of the rib 13 farther from the substrate. The inventors found that, by selecting a difference between a lower-rib-width W_(L) and an upper-rib-width W_(H) of greater than 20 nanometers, for a wavelength range of light of at least 20 nanometers in the ultraviolet spectrum, the E_(∥) transmission divided by the E_(⊥) transmission can be at least 300. The ribs 13 can be formed with a different lower-rib-width W_(L) and an upper-rib-width W_(H) by adjusting the anisotropic/isotropic character of the etch, and other etch parameters, throughout the etch process.

WGPs described herein can be made with E_(∥) transmission >E_(⊥) transmission, with high contrast (E_(∥) transmission/E_(⊥) transmission), and with high E_(∥) transmission, even in the difficult to polarize regions of the electromagnetic spectrum. For example, the WGPs described herein can have E_(∥) transmission >E_(⊥) transmission and contrast of at least 10 in one aspect, at least 100 in another aspect, at least 300 in another aspect, at least 400 in another aspect, at least 1000 in another aspect, at least 5000 in another aspect, or at least 10,000 in another aspect, at a certain wavelength or wavelength range. As another example, the WGPs described herein can have E_(∥) transmission of at least 70&, at least 80%, or at least 90%, at a certain wavelength or wavelength range. These WGP performance numbers can even be achieved at a wavelength or a wavelength range of light in the electromagnetic spectrum of less than 400 nanometers in one aspect, less than 300 nanometers in another aspect, less than 270 nanometers in another aspect, or a wavelength in or across the ultraviolet spectrum in another aspect.

A method of polarizing light can comprise one or more of the following:

-   -   1. providing an inverse, embedded WGP as described herein; and     -   2. transmitting more E_(∥) through the WGP than E_(⊥) with         contrast (E_(∥) transmission/E_(⊥) transmission) as described         above and at a wavelength or wavelength range as described         herein.

A method of designing an embedded, inverse WGP can comprise one or more of the following for matching or tuning the inverse WGP performance (E_(∥) transmission >E_(⊥) transmission) to a desired wavelength or wavelength range and/or for improving WGP performance (contrast and/or % E_(∥) transmission) at that wavelength or wavelength range:

-   -   1. calculating a pitch of an array of ribs 13;     -   2. calculating an index of refraction of a fill-layer 15,         located over the array of ribs 13 and substantially filling gaps         16 between the ribs 13;     -   3. selecting rib 13 material;     -   4. selecting rib thickness Th₁₃;     -   5. selecting duty cycle (W/P);     -   6. selecting rib 13 shape;     -   7. selecting thickness Th₁₅ of the fill-layer 15 over the array         of ribs 13; and     -   8. selecting substrate material.

Integrated circuits (ICs or IC) can be made of semiconductor material and can include nanometer-sized features. ICs can be used in various electronic devices (e.g. computer, motion sensor, etc.). Defects in the IC can cause the electronic device to fail. Thus, inspection of the IC can be important for avoiding failure of the electronic device, while in use by the consumer. Such inspection can be difficult due to the small feature-size of IC components. Light, with small wavelengths (e.g. ultraviolet), can be used to inspect small feature-size components. It can be difficult to have sufficient contrast between these small feature-size components and defects or their surroundings. Use of polarized light can improve integrated circuit (IC) inspection contrast. It can be difficult to polarize the small wavelengths of light (e.g. ultraviolet/UV) used for IC inspection. Polarizers that can polarize such small wavelengths, and that can withstand exposure to high-energy wavelengths of light, may be needed.

The WGPs described herein can polarize small wavelengths of light (e.g. UV) and can be made of materials sufficiently durable to withstand exposure to such light. The fill-material 15 can protect the ribs 13 from UV light damage. An IC inspection tool 40 is shown in FIG. 4, comprising a light source 41 and a stage 42 for holding an IC wafer 43. The light source 41 can be located to emit an incident light-beam 45 (e.g. visible, ultraviolet, or x-ray) onto the IC wafer 43. The incident light-beam 45 can be directed to the wafer 43 by optics (e.g. mirrors). The incident light-beam 45 can have an acute angle of incidence 49 with a face of the wafer 43. To improve inspection contrast, a WGP 44 (according to an embodiment described herein) can be located in, and can polarize, the incident light-beam 45.

A detector 47 (e.g. CCD) can be located to receive an output light-beam 46 from the IC wafer 43. An electronic circuit 48 can be configured to receive and analyze a signal from the detector 47 (the signal based on the output light-beam 46 received by the detector 47). To improve inspection contrast, a WGP 44 (according to an embodiment described herein) can be located in, and can polarize, the output light-beam 46.

The WGPs described herein can be used in the manufacture of flat panel displays (FPDs for plural or FPD for singular). FPDs can include an aligned polymer film and liquid crystal. An FPD manufacturing tool 50 is shown in FIG. 5, comprising a light source 51, a stage 52 for holding an FPD 53, and a WGP 54 (according to an embodiment described herein). The light source 51 can emit ultraviolet light 55. The WGP 54 can be located between the light source 51 and the stage 52 and can polarize the ultraviolet light 55. Exposing the FPD 53 to polarized ultraviolet light 55 can align the polymer film. See U.S. Pat. Nos. 8,797,643 and 8,654,289, both incorporated herein by reference. Exposing the FPD 53 to polarized ultraviolet light 55 can help repair the FPD 53. See U.S. Pat. No. 7,697,108, which is incorporated herein by reference. 

What is claimed is:
 1. An embedded, inverse wire-grid polarizer (WGP) comprising: ribs located over a surface of a transparent substrate, the ribs being elongated and formed into an array, the ribs are metallic; at a wavelength of light incident upon the WGP in a range ≥175 nm, E_(∥) transmission >E_(⊥) transmission, where E_(∥) is a polarization of the light with an electric field oscillation parallel to a length of the ribs and E_(⊥) is a polarization of the light with an electric field oscillation perpendicular to a length of the ribs; gaps between the ribs and a fill-layer substantially filling the gaps; and at the wavelength of the light, the ribs are reflective, the fill-layer is transparent, and the fill-layer has an index of refraction greater than 1.7.
 2. A method of using the WGP of claim 1, comprising transmitting more E_(∥) through the WGP than E_(⊥) at the wavelength of light.
 3. The method of claim 2, wherein inverse polarization occurs at a wavelength of less than 400 nanometers and a pitch P of the ribs is greater than 140 nanometers.
 4. An embedded, inverse wire-grid polarizer (WGP) comprising: ribs located over a surface of a transparent substrate, the ribs being elongated and formed into an array; at a wavelength of light incident upon the WGP in a range ≥175 nm, E_(∥) transmission >E_(⊥) transmission, where E_(∥) is a polarization of the light with an electric field oscillation parallel to a length of the ribs and E_(⊥) is a polarization of the light with an electric field oscillation perpendicular to a length of the ribs; gaps between the ribs; and a fill-layer substantially filling the gaps and extending from the gaps over the ribs such that the fill-layer in each gap extends continuously over adjacent ribs to the fill-layer in each adjacent gap, the fill-layer being transparent and having an index of refraction greater than 1.7.
 5. The WGP of claim 1, wherein the fill-layer substantially fills the gaps and extends from the gaps over the ribs such that the fill-layer in each gap extends continuously over adjacent ribs to the fill-layer in each adjacent gap.
 6. The WGP of claim 1, wherein a cross-sectional profile of the ribs includes a rounded shape.
 7. The WGP of claim 1, wherein an end of the ribs farther from the substrate has a rounded-shape.
 8. The WGP of claim 1, wherein an end of the ribs closest to the substrate is rounded.
 9. The WGP of claim 1, wherein a difference between a lower-rib-width and an upper-rib-width is greater than 20 nanometers, where lower-rib-width means a maximum width of the ribs in a lower-half of the rib closer to the substrate and upper-rib-width means a maximum width of the ribs in an upper-half of the rib farther from the substrate.
 10. The WGP of claim 1, wherein the fill-layer comprises aluminum oxide.
 11. The WGP of claim 1, wherein the fill-layer comprises silicon nitride, tantalum oxide, tellurium oxide, germanium oxide, zirconium oxide, hafnium oxide, a rare earth oxide, or combinations thereof.
 12. The WGP of claim 1, further comprising a thin-film between the ribs and the substrate, and at the wavelength of the light, the thin-film has an index of refraction greater than 1.5.
 13. The WGP of claim 1, further comprising a thin-film between the ribs and the substrate, and at the wavelength of the light, the thin-film has an index of refraction greater than 1.6.
 14. The WGP of claim 1, further comprising a thin-film between the ribs and the substrate, and at the wavelength of the light, the thin-film has an index of refraction greater than 1.8.
 15. The WGP of claim 4, wherein the fill-layer substantially fills the gaps and extends from the gaps over the ribs such that the fill-layer in each gap extends continuously over adjacent ribs to the fill-layer in each adjacent gap.
 16. A method of using the WGP of claim 15, comprising transmitting more E_(∥) through the WGP than E_(⊥) at the wavelength of light.
 17. The WGP of claim 15, wherein the fill-layer comprises aluminum oxide.
 18. The WGP of claim 15, wherein an end of the ribs farther from the substrate has a rounded-shape.
 19. The WGP of claim 15, wherein an end of the ribs closest to the substrate is rounded.
 20. The WGP of claim 15, wherein a difference between a lower-rib-width and an upper-rib-width is greater than 20 nanometers, where lower-rib-width means a maximum width of the ribs in a lower-half of the rib closer to the substrate and upper-rib-width means a maximum width of the ribs in an upper-half of the rib farther from the substrate. 